2006 Candidate degree in physical and mathematical science
Education
2022 Повышение квалификации: Самарский университет, Инклюзивное профессиональное образование
2022 Повышение квалификации: Самарский университет, Навыки оказания первой помощи
2021 Повышение квалификации: Самарский университет, Электронная информационно-образовательная среда университета
2018 Повышение квалификации: Самарский университет, "Навыки оказания первой помощи"
2018 Повышение квалификации: Самарский университет, Электронная информационно-образовательная среда университета
2018 Повышение квалификации: Самарский университет, "Инклюзивное профессиональное образование"
2017 Стажировка: ICAOP, г.Хисар (Индия)
2016 Повышение квалификации: INDIAN INSTITUTE OF TECHNOLOGY DELHI
2016 Повышение квалификации: Indian institute of Technology Delhi
2014 - 2015 Повышение квалификации: СГАУ
2014 Повышение квалификации: СГАУ
2014 Повышение квалификации: ООО "Альт Линукс" г.Москва
2012 Повышение квалификации: Пекинский политехнический институт, г.Пекин, Китай
2012 Повышение квалификации: Шанхайский университет науки и технологий, г.Шанхай, Китай
2011 Повышение квалификации: Ульяновский гос. университет
1997 - 2003 Высшее: Самарский государственный аэрокосмический университет имени академика С.П.Королева, факультет Информатика
2024
1Stafeev S.S., Nalimov A.G., Kozlova E.S. etc. Zone Plate Based Method for Measurement of Shift or Thickness // 2024 Photonics and Electromagnetics Research Symposium, PIERS 2024 - Proceedings. — 2024. —
2Kotlyar V.V., Kovalev A.A., Stafeev S.S. etc. Spin-orbit Conversion of Vector Light Field Just after Spherical Lens // 2024 Photonics and Electromagnetics Research Symposium, PIERS 2024 - Proceedings. — 2024. —
4Kotlyar V.V., Kovalev A.A., Nalimov A.G. etc. Transverse and Longitudinal Energy Flows in a Sharp Focus of Vortex and Cylindrical Vector Beams // Applied Sciences (Switzerland) 2024. — Vol. 14. Issue 14. № 14.
3Kotlyar V.V., Kovalev A.A., Nalimov A.G.Propagation of hypergeometric laser beams in a medium with a parabolic refractive index // Journal of Optics 2013. — Vol. 15. Issue 12.
4Kotlyar V.V., Kovalev A.A., Stafeev S.S. etc. An asymmetric optical vortex generated by a spiral refractive plate // Journal of Optics 2013. — Vol. 15. Issue 2.
5Nalimov A.G., Kotlyar V.V.Hyperbolic secant slit lens for subwavelength focusing of light // Optics Letters 2013. — Vol. 38. Issue 15. — P. 2702-2704
6Nalimov A.G., Kotlyar V.V.Tight light localization in a hyperbolic secant planar slit lens // Proceedings of the International Conference on Advanced Optoelectronics and Lasers, CAOL. — 2013. — P. 237-239
7Nalimov A.G., Kotlyar V.V.Hyperbolic secant lens with a slit for subwavelength light focusing // Computer Optics 2013. — Vol. 37. Issue 1. — P. 19-24
2004
1Korsakova S.S., Nalimov A.G., Khonina S.N.A method of calculating the diffraction and refraction of radiation at a dielectric cylinder // Journal of Optical Technology . — 2004. — Vol. 71. Issue 7. — P. 472-477
2005
1Kotlyar V.V., Nalimov A.G., Skidanov R.V.Calculation of Umov-Poynting vector and the electromagnetic wave pressure force on a homogeneous dielectric cylinder // Proceedings of SPIE - The International Society for Optical Engineering. — 2005. — Vol. 5773. — P. 106-118
2Kotlyar V.V., Skidanov R.V., Nalimov A.G.Method for rapidly calculating the diffraction of laser radiation at microscopic objects // Journal of Optical Technology 2005. — Vol. 72. Issue 5. — P. 400-405
2006
1Kotlyar V.V., Nalimov A.G.Calculating the pressure force of the non-paraxial cylindrical Gaussian beam exerted upon a homogeneous circular-shaped cylinder // Journal of Modern Optics 2006. — Vol. 53. Issue 13. — P. 1829-1844
2Kotlyar V.V., Nalimov A.G.Analytical expression for radiation forces on a dielectric cylinder illuminated by a cylindrical Gaussian beam // Optics Express 2006. — Vol. 14. Issue 13. — P. 505-510
3Kotlyar V.V., Nalimov A.G.Analytical expression for radiation forces on a dielectric cylinder illuminated by a cylindrical gaussian beam // Optics Express 2006. — Vol. 14. Issue 13. — P. 6316-6321
2008
1Kotlyar V.V., Nalimov A.G.Calculating of a periodic structures for the uniform light outut from a planar waveguide // Computer Optics 2008. — Vol. 32. Issue 3. — P. 249-252
2009
1Nalimov A.G., Kovalev A.A., Kotlyar V.V. etc. Three-dimensional simulation of a nanophotonics device with use of fullwave software // Optical Memory and Neural Networks (Information Optics) 2009. — Vol. 18. Issue 2. — P. 85-92
2Kotlyar V.V., Kovalev A.A., Nalimov A.G.Gradient-index elements of microoptics for superresolution // Computer Optics 2009. — Vol. 33. Issue 4. — P. 369-378
3Nalimov A.G., Kovalev A.A., Kotlyar V.V. etc. Simulation of 3D nanophotonics device for coupling light into planar waveguide // Computer Optics 2009. — Vol. 33. Issue 1. — P. 4-9
2010
1STRILEC T.S., KOTLYaR V.V., NALIMOV A.G. Моделирование волноводных режимов в многослойных структурах // Computer Optics 2010. — № т. 34, № 4.. — P. 487-494
2KOTLYaR V.V., KOVALEV A.A., NALIMOV A.G. etc. Механизм сверхразрешения в планарной гиперболической секансной линзе // Computer Optics 2010. — № т. 34, № 4.. — P. 428-435
3KOTLYaR V.V., KOVALEV A.A., NALIMOV A.G. etc. Субволновая локализация света в волноводных структурах // Computer Optics 2010. — № том 34,№2. — P. 169-185
6KOVALEV A.A., KOTLYaR V.V., NALIMOV A.G.Secant gradient-index microlens for superresolution // Int.Conf.on Opt/ Techn. and Nano-Tools for Mater. and Lefe sc.. — 2010. — P. 36
7KOTLYaR V.V., NALIMOV A.G., STAFEEV S.S. etc. Диаметр светового пятна в ближней зоне бинарного дифракционного микроаксикона // Computer Optics 2010. — № Т 34 №1. — P. 24-34
8Strilets T.S., Kotlyar V.V., Nalimov A.G.Simulation of waveguide modes in multilayer structures // Computer Optics 2010. — Vol. 34. Issue 4. — P. 487-493
9Kotlyar V.V., Kovalev A.A., Triandafilov Y.R. etc. Modes of planar gradient-index hyperbolic secant waveguide // Computer Optics 2010. — Vol. 34. Issue 2. — P. 146-155
10Kotlyar V.V., Stafeev S.S., Skidanov R.V. etc. Light spot diameter in the near zone of binary diffractive microaxicon // Computer Optics 2010. — Vol. 34. Issue 1. — P. 24-34
11Kotlyar V.V., Kovalev A.A., Shuyupova Y.O. etc. Subwavelength localization of light in waveguide structures // Computer Optics 2010. — Vol. 34. Issue 2. — P. 169-186
12Kotlyar V.V., Kovalev A.A., Nalimov A.G. etc. Mechanism of superresolution in a planar hyperbolicsecant lens // Computer Optics 2010. — Vol. 34. Issue 4. — P. 428-435
2011
1Kotlyar V.V., Nalimov A.G., Stafeev S.S.Diameter of a focal spot for non-Gaussian beams with a finite energy // Computer Optics 2011. — Vol. 35. Issue 4. — P. 452-459
2Nalimov A.G., Kotlyar V.V., Soifer V.A.Modeling of an image forming by a zone plate in X-ray // Computer Optics 2011. — Vol. 35. Issue 3. — P. 290-296
3Nalimov A.G., Kotlyar V.V., Kovalev A.A. etc. Three-dimensional simulation of a device to input light in a planar waveguide // Conference Proceedings - 11th International Conference on Laser and Fiber-Optical Networks Modeling, LFNM 2011. — 2011. —
4Kotlyar V.V., Kovalev A.A., Triandafilov Ya.R. etc. Simulation of propagation of modes in planar gradient-index hyperbolic secant waveguide // Conference Proceedings - 11th International Conference on Laser and Fiber-Optical Networks Modeling, LFNM 2011. — 2011. —
5KOTLYaR V.V., NALIMOV A.G., STAFEEV S.S.Диаметр фокусного пятна для негауссовых пучков с конечной энергией // Computer Optics 2011. — № т. 35, № 4.. — P. 452-459
6Kotlyar V.V., Nalimov A.G., Shanina M.I. etc. Zone plate on a film for hard X-ray radiation // Computer Optics 2011. — Vol. 35. Issue 1. — P. 36-41
7KOTLYaR V.V., NALIMOV A.G., Shanina M.I. etc. Зонная пластинка на мембране для жёсткого рентгеновского излучения // Computer Optics 2011. — № Том 35, № 1. — P. 36-42
3Kotlyar V.V., Stafeev S.S., Kovalev A.A. etc. Focusing of linearly polarized light using binary axicon with subwavelength period // Computer Optics 2012. — Vol. 36. Issue 2. — P. 183-189
4KOTLYaR V.V., STAFEEV S.S., NALIMOV A.G. etc. Моделирование фокусировки линейно-поляризованного света с помощью субволнового бинарного аксикона // Computer Optics 2012. — № 36(2). — P. 183-189
5Kotlyar V.V., Kovalev A.A., Nalimov A.G.Hypergeometric laser beams in a parabolic waveguide // Computer Optics 2012. — Vol. 36. Issue 3. — P. 308-315
8Kovalev A.A., Nalimov A.G., Kotlyar V.V.Subwavelength imaging with magnification by mikaelian lenses // Computer Optics 2012. — Vol. 36. Issue 4. — P. 497-505
9Kotlyar V.V., Nalimov A.G., Shanina M.I. etc. Focusing properties of a zone plate investigation for a hard x-ray // Computer Optics 2012. — Vol. 36. Issue 1. — P. 65-71
2014
1Nalimov A.G., Stafeev S.S., O'Faolain L. etc. Four-zone reflective polarization conversion plate // Progress in Biomedical Optics and Imaging - Proceedings of SPIE. — 2014. — Vol. 9448.
3Nalimov A.G., O'Faolain L., Stafeev S.S. etc. Reflected four-zones subwavelength microoptics element for polarization conversion from linear to radial // Computer Optics 2014. — Vol. 38. Issue 2. — P. 229-236
2Kotlyar V.V., Nalimov A.G., Kovalev A.A.Controlling the Spin Hall Effect in the Sharp Focus of an Axial Superposition of Two Optical Vortices with Left- and Right-Handed Circular Polarization // Applied Sciences (Switzerland) 2023. — Vol. 13. Issue 14. № 14.
3Nalimov A.G., Kotlyar V.V.Multifocal metalens for detecting several topological charges at different wavelengths // Computer Optics 2023. — Vol. 47. Issue 2. № 2. — P. 201-207
4Nalimov A., Stafeev S., Kotlyar V. etc. Optical Sensor Methodology for Measuring Shift, Thickness, Refractive Index and Tilt Angle of Thin Films // PHOTONICS 2023. — Vol. 10. Issue 6. № 6.
5Nalimov A.G., Kotlyar V.V., Khanenko Y.V.Calculation of the intensity at the sharp focus of a cylindrical vector beam by three methods // Computer Optics 2023. — Vol. 47. Issue 5. № 5. — P. 734-741
6Kovalev A.A., Kotlyar V.V., Nalimov A.G.Spin Hall Effect in Paraxial Vectorial Light Beams with an Infinite Number of Polarization Singularities // MICROMACHINES 2023. — Vol. 14. Issue 7. № 7.
7Nalimov A., Kotlyar V., Stafeev S. etc. Metalens for Detection of a Topological Charge // Optical Memory and Neural Networks (Information Optics) 2023. — Vol. 32. — P. S187-S194
2015
1Kozlova E.S., Kotlyar V.V., Nalimov A.G.Comparative modeling of amplitude and phase zone plates // Computer Optics 2015. — Vol. 39. Issue 5. — P. 687-693
2Nalimov A.G., Kotlyar V.V.Use of combined zone plates as imaging optics for hard X-rays // Computer Optics 2015. — Vol. 39. Issue 1. — P. 52-57
3Stafeev S.S., O'Faolain L., Kotlyar V.V. etc. Tight focus of light using micropolarizer and microlens // Applied Optics 2015. — Vol. 54. Issue 14. — P. 4388-4394
4Stafeev S.S., Nalimov A.G., Kotlyar M. V. etc. A four-zone reflective azimuthal micropolarizer // Computer Optics 2015. — Vol. 39. Issue 5. — P. 709-715
2016
1Kotlyar V.V., Nalimov A.G., Kotlyar M. V. Modeling a polarization microlens to focus linearly polarized light into a near-circular subwavelength focal spot // Computer Optics 2016. — Vol. 40. Issue 4. — P. 451-457
2Stafeev S.S., Kotlyar M. V. , O’Faolain L. etc. A four-zone transmission azimuthal micropolarizer with phase shift // Computer Optics 2016. — Vol. 40. Issue 1. — P. 12-18
3Stafeev S.S., Nalimov A.G., Kotlyar M. V. etc. Subwavelength focusing of laser light of a mixture of linearly and azimuthally polarized beams // Computer Optics 2016. — Vol. 40. Issue 4. — P. 458-466
4Stafeev S.S., Kotlyar M. V. , O'Faolain L. etc. Subwavelength gratings for generating azimuthally polarized beams // CEUR Workshop Proceedings. — 2016. — Vol. 1638. — P. 125-131
5Kotlyar V.V., Nalimov A.G.Tightly focused laser light with azimuthal polarization and singular phase // Computer Optics 2016. — Vol. 40. Issue 5. — P. 642-648
6Nalimov A.G., Kotlyar V.V.Sharp focusing of light using a planar gradient microlens // Computer Optics 2016. — Vol. 40. Issue 2. — P. 135-140
7Stafeev S.S., Nalimov A.G., O'Faolain L. etc. The tight focusing of laser radiation using 4-sector polarization converter // Journal of Physics: Conference Series. — 2016. — Vol. 735. Issue 1.
8Stafeev S.S., Nalimov A.G., Kotlyar M. V. etc. Microlens-aided focusing of linearly and azimuthally polarized laser light // Optics Express 2016. — Vol. 24. Issue 26. — P. 29800-29813
9Kotlyar V.V., Stafeev S.S., Kotlyar M. V. etc. Subwavelength micropolarizer in a gold film for visible light // Applied Optics 2016. — Vol. 55. Issue 19. — P. 5025-5032
10Nalimov A.G., Kotlyar V.V.Simulation of image formation using compound X-ray zone plates // OPTIK 2016. — Vol. 127. Issue 18. — P. 7235-7241
2017
1Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. Tight focusing of circularly polarized laser light by amplitude zone plate with chromium rings // Progress in Electromagnetics Research Symposium. — 2017. — Vol. 2017-November. — P. 2501-2505
2Stafeev S.S., Nalimov A.G., O’Faolain L. etc. Binary diffraction gratings for controlling polarization and phase of laser light [review] // Computer Optics 2017. — Vol. 41. Issue 3. — P. 299-314
3Nalimov A.G., Kotlyar V.V., Konov V.I. Simulation of hard X-ray focusing using an array of cylindrical micro-holes in a diamond film // Computer Optics 2017. — Vol. 41. Issue 6. — P. 796-802
4Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. Tight focusing of laser light using a chromium Fresnel zone plate // Optics Express 2017. — Vol. 25. Issue 17. — P. 19662-19671
6Stafeev S.S., Nalimov A.G., O'Faolain L. etc. Azimuthal polarizer with phase shift for subwavelength focusing of laser light // Proceedings of SPIE - The International Society for Optical Engineering. — 2017. — Vol. 10176.
7Kozlova E.S., Kotlyar V.V., Nalimov A.G. etc. Subwavelength focusing of laser light using zone plates with silver and chromium rings // Progress in Electromagnetics Research Symposium. — 2017. — P. 107-111
8Stafeev S.S., Nalimov A.G., Kotlyar M. V. etc. Transmitting subwavelength azimuthal micropolarizer // Proceedings of SPIE - The International Society for Optical Engineering. — 2017. — Vol. 10337.
9Nalimov A.G., Kotlyar V.V.Subwavelength focus of light by a planar microlens // Journal of Modern Optics 2017. — Vol. 64. Issue 5. — P. 478-483
10Kotlyar V.V., Nalimov A.G.A vector optical vortex generated and focused using a metalens // Computer Optics 2017. — Vol. 41. Issue 5. — P. 645-654
11Nalimov A.G., Stafeev S.S., Kozlova E.S. etc. Subwavelength focusing of laser light using a chromium zone plate // Computer Optics 2017. — Vol. 41. Issue 3. — P. 356-362
12Kotlyar V.V., Nalimov A.G., Stafeev S.S. etc. A metalens for subwavelength focus of light // Progress in Electromagnetics Research Symposium. — 2017. — P. 112-117
13Kozlova E.S., Kotlyar V.V., Nalimov A.G. etc. Dependence of the focal spot parameters on the relief height of the amplitude zone plate // International Conference on Transparent Optical Networks. — 2017. —
14Nalimov A.G., Kotlyar V.V., Kozlova E.S.Metalens investigation with different sectors number // Progress in Electromagnetics Research Symposium. — 2017. — Vol. 2017-November. — P. 2509-2512
15Stafeev S.S., Nalimov A.G., Kotlyar M. V. etc. Tight focusing of azimuthally polarized optical vortex produced by subwavelength grating // Procedia Engineering. — 2017. — Vol. 201. — P. 83-89
16Kotlyar V.V., Nalimov A.G., Stafeev S.S. etc. Thin metalens with high numerical aperture // Computer Optics 2017. — Vol. 41. Issue 1. — P. 5-12
17Stafeev S.S., Nalimov A.G., O'Faolain L. etc. Tight focusing of laser light propagated through subwavelength micropolarizer using Fresnel zone plate // Proceedings of SPIE - The International Society for Optical Engineering. — 2017. — Vol. 10342.
18Stafeev S.S., Nalimov A.G., Kotlyar M. V. etc. Focusing zone plate based on subwavelength grating // International Conference on Transparent Optical Networks. — 2017. —
19Nalimov A.G.Modeling a high numerical aperture micrometalens simulation with and a varying number of sectors // Computer Optics 2017. — Vol. 41. Issue 5. — P. 655-660
1Kotlyar V.V., Nalimov A.G., Kovalev A.A.Helical reverse flux of light of a focused optical vortex // Journal of Optics 2018. — Vol. 20. Issue 9.
2Nalimov A.G., Kotlyar V.V.Design of a sector-variant high-numerical-aperture micrometalens // OPTIK 2018. — Vol. 159. — P. 9-13
3Kotlyar V.V., Nalimov A.G., Stafeev S.S.The near-axis backflow of energy in a tightly focused optical vortex with circular polarization // Computer Optics 2018. — Vol. 42. Issue 3. — P. 392-400
4Stafeev S.S., Nalimov A.G., Kotlyar V.V.Energy Backflow in Tightly Focused Optical Vortex // International Conference on Transparent Optical Networks. — 2018. — Vol. 2018-July.
5Stafeev S.S., Nalimov A.G., Kotlyar V.V.Negative longitudinal component of the Poynting vector of tightly focused optical vortex // Proceedings - International Conference Laser Optics 2018, ICLO 2018. — 2018. — P. 204
6Kotlyar V.V., Nalimov A.G.Sharp focusing of vector optical vortices using a metalens // Journal of Optics 2018. — Vol. 20. Issue 7.
7Stafeev S.S., Nalimov A.G.Longitudinal component of the poynting vector of a tightly focused optical vortex with circular polarization // Computer Optics 2018. — Vol. 42. Issue 2. — P. 190-196
8Stafeev S.S., Nalimov A.G., O'faolain L. etc. Effects of fabrication errors on the focusing performance of a sector metalens // Computer Optics 2018. — Vol. 42. Issue 6. — P. 970-976
9Nalimov A.G., Kotlyar V.V., Kononenko T.V. etc. An X-ray diamond focuser based on an array of three-component elements // Computer Optics 2018. — Vol. 42. Issue 6. — P. 933-940
11Kotlyar V.V., Kovalev A.A., Nalimov A.G.Energy density and energy flux in the focus of an optical vortex: Reverse flux of light energy // Optics Letters 2018. — Vol. 43. Issue 12. — P. 2921-2924
12Stafeev S.S., Nalimov A.G., O'Faolain L. etc. Subwavelength focusing of azimuthally polarized optical vortex // Proceedings of SPIE - The International Society for Optical Engineering. — 2018. — Vol. 10774.
14Stafeev S.S., Nalimov A.G., O'Faolain L. etc. Tight focusing of a nonhomogeneously polarized optical vortex // Progress in Biomedical Optics and Imaging - Proceedings of SPIE. — 2018. — Vol. 10717.
15Kotlyar V.V., Kovalev A.A., Nalimov A.G.Backward flow of energy for an optical vortex with arbitrary integer topological charge // Computer Optics 2018. — Vol. 42. Issue 3. — P. 408-413
16Stafeev S.S., Nalimov A.G., Kotlyar V.V.Longitudinal component of the Poynting vector of tightly focused cylindrical vector beam // Journal of Physics: Conference Series. — 2018. — Vol. 1135. Issue 1.
17Stafeev S.S., Nalimov A.G., Kotlyar V.V.Energy backflow in the focal spot of a cylindrical vector beam // Computer Optics 2018. — Vol. 42. Issue 5. — P. 744-750
18Stafeev S.S., Nalimov A.G., Kotlyar M. V. etc. Subwavelength Gratings for Polarization Control // Journal of Physics: Conference Series. — 2018. — Vol. 1096. Issue 1.
2019
1Stafeev S.S., Kotlyar V.V., Nalimov A.G. etc. The Non-Vortex Inverse Propagation of Energy in a Tightly Focused High-Order Cylindrical Vector Beam // IEEE PHOTONICS JOURNAL 2019. — Vol. 11. Issue 4.
2Kotlyar V.V., Stafeev S.S., Nalimov A.G.Energy backflow in the focus of a light beam with phase or polarization singularity // Physical Review A 2019. — Vol. 99. Issue 3.
3Kotlyar V.V., Nalimov A.G., Stafeev S.S.Exploiting the circular polarization of light to obtain a spiral energy flow at the subwavelength focus // Journal of the Optical Society of America B: Optical Physics 2019. — Vol. 36. Issue 10. — P. 2850-2855
4Stafeev S.S., Kotlyar V.V., Nalimov A.G. etc. Focusing of laser light by sectoral spiral metalens // Proceedings of SPIE - The International Society for Optical Engineering. — 2019. — Vol. 11025.
6Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. Two-petal laser beam near a binary spiral axicon with topological charge 2 // Optics and laser technology 2019. — Vol. 119.
7Stafeev S.S., Nalimov A.G., Kotlyar V.V.Tight Focusing of a Second-order Cylindrical Vector Beam // Progress in Electromagnetics Research Symposium. — 2019. — Vol. 2019-June. — P. 3254-3257
8Kotlyar V.V., Nalimov A.G., Stafeev S.S.Backward Energy Flux in Sharp Focus of Beams with Linear and Circular Polarization // Progress in Electromagnetics Research Symposium. — 2019. — Vol. 2019-June. — P. 335-338
9Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. Subwavelength grating-based spiral metalens for tight focusing of laser light // Applied Physics Letters 2019. — Vol. 114. Issue 14.
10Kotlyar V.V., Nalimov Anton Gennadevich, Stafeev S.S.Comparison of the negative energy flow in linearly and circularly polarized beams focused with metalens // The 10th International Conference on Metamaterials, Photonic Crystals and Plasmonics META-2019. — 2019. — P. 1687-1688
11Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. Formation of the reverse flow of energy in a sharp focus // Computer Optics 2019. — Vol. 43. Issue 5. — P. 714-722
12Nalimov A.G., Kotlyar V.V.Sharp focus of a circularly polarized optical vortex at the output of a metalens illuminated by linearly polarized light // Computer Optics 2019. — Vol. 43. Issue 4. — P. 528-534
13Kotlyar V.V., Nalimov A.G., Stafeev S.S. etc. Single metalens for generating polarization and phase singularities leading to a reverse flow of energy // Journal of Optics 2019. — Vol. 21. Issue 5.
14Stafeev S.S., Kotlyar V.V., Nalimov A.G.Energy backflow in in a tightly focused high-order cylindrical vector beam // Proceedings of SPIE - The International Society for Optical Engineering. — 2019. — Vol. 11025.
15Stafeev S.S., Nalimov A.G., Kotlyar V.V.Metalens for polarization conversion and focusing of laser light // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 2.
16Stafeev S.S., Nalimov A.G., O'Faolain L. etc. Sector Metalens for Sharp Focusing of Laser Light // Progress in Electromagnetics Research Symposium. — 2019. — Vol. 2019-June. — P. 4248-4251
17Kotlyar V.V., Nalimov A.G., Stafeev S.S.Comparison of backward flow values in the sharp focus of light fields with polarization and phase singularity // Computer Optics 2019. — Vol. 43. Issue 2. — P. 174-183
2020
1Nalimov A.G.Optical force acting on a particle in the presence of a backward energy flow near the focus of a gradient lens // Computer Optics 2020. — Vol. 44. Issue 6. — P. 871-875
2Stafeev S.S., Kozlova E.S., Nalimov A.G. etc. Poynting vector behavior of cylindrical vector beam focused by gradient index lens // International Conference on Transparent Optical Networks. — 2020. — Vol. 2020-July.
3Nalimov A., Kotlyar V., Stafeev S.Torque on an ellipsoidal dielectric particle in a gaussian beam with circular polarization // International Conference on Transparent Optical Networks. — 2020. — Vol. 2020-July.
4Kotlyar V.V., Nalimov A.G., Kovalev A.A. etc. Spin-orbit and orbit-spin conversion in the sharp focus of laser light: Theory and experiment // Physical Review A 2020. — Vol. 102. Issue 3.
5Nalimov A.G., Stafeev S.S., Kotlyar V.V.Optical force acting on a particle in a reverse energy flow near the focus of a gradient lens // Journal of Optics 2020. — Vol. 22. Issue 11.
6Nalimov A.G., Kotlyar V.V.Rotation of an ellipsoidal dielectric particle in the focus of a circularly polarized gaussian beam // OPTIK 2020. — Vol. 222.
7Stafeev S.S., Kozlova E.S., Nalimov A.G. etc. Tight focusing of a cylindrical vector beam by a hyperbolic secant gradient index lens // Optics Letters 2020. — Vol. 45. Issue 7. — P. 1687-1690
8Nalimov A.G., Kozlova E.S.Inversion of the longitudinal component of spin angular momentum in the focus of a left-handed circularly polarized beam // Computer Optics 2020. — Vol. 44. Issue 5. — P. 699-706
9Kotlyar V.V., Kovalev A.A., Nalimov A.G. etc. Evolution of an optical vortex with an initial fractional topological charge // Physical Review A 2020. — Vol. 102. Issue 2.
10Stafeev S.S., Nalimov A.G., Kotlyar V.V.Strong negative longitudinal component of the Poynting vector in a tightly focused cylindrical vector beam // Journal of Physics: Conference Series. — 2020. — Vol. 1461. Issue 1.
11Kotlyar V.V., Stafeev S.S., Nalimov A.G.Vortex energy flow in the tight focus of a non-vortex field with circular polarization // Computer Optics 2020. — Vol. 44. Issue 1. — P. 5-11
12Kudryashov S., Danilov P., Rupasov A. etc. Energy deposition parameters revealed in the transition from 3D to 1D femtosecond laser ablation of fluorite at high-NA focusing // Optical Materials Express 2020. — Vol. 10. Issue 12. — P. 3291-3305
13Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. Experimental investigation of the energy backflow in the tight focal spot // Computer Optics 2020. — Vol. 44. Issue 6. — P. 863-870
14Kotlyar V.V., Nalimov A.G., Stafeev S.S. etc. Orbital energy and spin flows in a strong focus of laser light // IEEE PHOTONICS JOURNAL 2020. — Vol. 12. Issue 5.
15Kotlyar V.V., Nalimov A.G., Stafeev S.S.Inversion of the axial projection of the spin angular momentum in the region of the backward energy flow in sharp focus // Optics Express 2020. — Vol. 28. Issue 23. — P. 33830-33840
16Nalimov A., Kotlyar V., Stafeev S.Optimizing of Poynting vector and light intensity after secant gradient lens // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
17Nalimov A.G., Stafeev S.S.Energy flux of a vortex field focused using a secant gradient lens // Computer Optics 2020. — Vol. 44. Issue 5. — P. 707-711
18Kotlyar V.V., Nalimov A.G., Kovalev A.A. etc. Transfer of spin angular momentum to a dielectric particle // Computer Optics 2020. — Vol. 44. Issue 3. — P. 333-342
19Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. Mechanism of formation of an inverse energy flow in a sharp focus // Physical Review A 2020. — Vol. 101. Issue 3.
20Nalimov A.G., Stafeev S.S.Rotation of an elliptical dielectric particle in the focus of a circularly polarized gaussian beam // Computer Optics 2020. — Vol. 44. Issue 4. — P. 561-567
21Stafeev S.S., Kozlova E.S., Nalimov A.G.Focusing a second-order cylindrical vector beam with a gradient index mikaelian lens // Computer Optics 2020. — Vol. 44. Issue 1. — P. 29-33
2021
1Kotlyar V.V., Stafeev S.S., Nalimov A.G.Focusing of a vector beam with c-lines of polarization singularity // Computer Optics 2021. — Vol. 45. Issue 6. — P. 800-808
2Stafeev S.S., Kozlova E.S., Nalimov A.G. etc. Tight focusing of second-order cylindrical vector beam by Mikaelian lens // Journal of Physics: Conference Series. — 2021. — Vol. 1745. Issue 1.
3Kotlyar V.V., Nalimov A.G.Evolution of an optical vortex with initial fractional topological charge // Computer Optics 2021. — Vol. 45. Issue 1. — P. 5-12
4Kotlyar V.V., Kovalev A.A., Nalimov A.G.Astigmatic transformation of a set of edge dislocations embedded in a gaussian beam // Computer Optics 2021. — Vol. 45. Issue 2. — P. 190-199
5Kotlyar V.V., Stafeev S.S., Nalimov A.G. etc. A dual-functionality metalens to shape a circularly polarized optical vortex or a second-order cylindrical vector beam // Photonics and Nanostructures - Fundamentals and Applications 2021. — Vol. 43.
6Kotlyar V.V., Nalimov A.G., Stafeev S.S. etc. Sharp focusing of beams with v-point polarization singularities // Computer Optics 2021. — Vol. 45. Issue 5. — P. 643-653
7Kotlyar V.V., Nalimov A.G.Focusing a vortex laser beam and converting linear to circular polarization // Laser physics 2021. — Vol. 31. Issue 11.
9Kotlyar V.V., Kovalev A.A., Nalimov A.G.Optical phase singularities going to and coming from infinity with a higher-than-light speed // Computer Optics 2021. — Vol. 45. Issue 5. — P. 654-660
10Kovalev A.A., Kotlyar V.V., Kalinkina D.S. etc. Off-axis elliptic gaussian beams with an intrinsic orbital angular momentum // Computer Optics 2021. — Vol. 45. Issue 6. — P. 809-817
11Nalimov A.G., Stafeev S.S.Linear to circular polarization conversion in the sharp focus of an optical vortex // Computer Optics 2021. — Vol. 45. Issue 1. — P. 13-18
12Kotlyar V.V., Kovalev A.A., Nalimov A.G.Optical phase singularities 'going to' infinity with a higher-than-light speed // Journal of Optics 2021. — Vol. 23. Issue 10.
13Kotlyar V.V., Stafeev S.S., Nalimov A.G.Sharp focusing of a hybrid vector beam with a polarization singularity // PHOTONICS 2021. — Vol. 8. Issue 6.
14Stafeev S.S., Nalimov A.G., Zaitsev V.D. etc. Tight focusing cylindrical vector beams with fractional order // Journal of the Optical Society of America B: Optical Physics 2021. — Vol. 38. Issue 4. — P. 1090-1096
15Kotlyar V.V., Kovalev A.A., Nalimov A.G.Transformation of a high-order edge dislocation to optical vortices (Spiral dislocations) // Computer Optics 2021. — Vol. 45. Issue 3. — P. 319-323
18Kotlyar V.V., Kovalev A.A., Nalimov A.G.Conservation of the half-integer topological charge on propagation of a superposition of two Bessel-Gaussian beams // Physical Review A 2021. — Vol. 104. Issue 3.
19Stafeev S.S., Nalimov A.G., Kotlyar V.V. etc. Metalens for energy backflow // Proceedings of SPIE - The International Society for Optical Engineering. — 2021. — Vol. 11793.
20Kotlyar V.V., Stafeev S.S., Kozlova E.S. etc. Spin-orbital conversion of a strongly focused light wave with high-order cylindrical–circular polarization // Sensors (Switzerland) 2021. — Vol. 21. Issue 19.
2022
1Nalimov A.G., Kotlyar V.V.Influence of optical "dipoles" on the topological charge of a field with a fractional initial charge // Journal of the Optical Society of America A: Optics and Image Science, and Vision 2022. — Vol. 39. Issue 5. — P. 812-819
3Kotlyar V., Nalimov A., Kovalev A. etc. Optical Polarization Sensor Based on a Metalens // Sensors (Switzerland) 2022. — Vol. 22. Issue 20. № 20.
4Kotlyar V.V., Abramochkin E.G., Kovalev A.A. etc. Astigmatic transformation of a fractional-order edge dislocation // Computer Optics 2022. — Vol. 46. Issue 4. № 4. — P. 522-530
5Kotlyar V.V., Kovalev A.A., Nalimov A.G.Control of an orbital angular momentum of a Gaussian beam using zero intensity lines // Proceedings of SPIE - The International Society for Optical Engineering. — 2022. — Vol. 12295.
7Kotlyar V.V., Kovalev A.A., Nalimov A.G.Superposition of Two Converging and Diverging Coaxial Hypergeometric Beams // Atmospheric and Oceanic Optics 2022. — Vol. 35. Issue 3. — P. 212-217
8Kotlyar V.V., Abramochkin E.G., Kovalev A.A. etc. An astigmatic transform of a fractional-order edge dislocation // Journal of Optics 2022. — Vol. 24. Issue 6.
10Stafeev S.S., Nalimov A.G., Kovalev A.A. etc. Circular Polarization near the Tight Focus of Linearly Polarized Light // PHOTONICS 2022. — Vol. 9. Issue 3.
11Nalimov A., Kotlyar V.Ultra-Thin, Short-Focus, and High-Aperture Metalens for Generating and Detecting Laser Optical Vortices // NANOMATERIALS 2022. — Vol. 12. Issue 15. № 15.
12Kotlyar V., Kovalev A., Nalimov A. etc. Preservation of Optical Vortex OAM after Distortion by a Diaphragm // Proceedings of the 2022 International Conference on Electrical Engineering and Photonics, EExPolytech 2022. — 2022. — P. 305-309
13Nalimov A.G., Kotlyar V.V.Topological charge of optical vortices in the far field with an initial fractional charge: optical "dipoles" // Computer Optics 2022. — Vol. 46. Issue 2. — P. 185-195
14Kotlyar V.V., Nalimov A.G.Evolution of a fractional-charge optical vortex upon free-space propagation // OPTIK 2022. — Vol. 261.
15Kotlyar V.V., Kovalev A.A., Nalimov A.G.Optical Vortex Beams with a Symmetric OAM Spectrum beyond a Sector Aperture // PHOTONICS 2022. — Vol. 9. Issue 10. № 10.
16Nalimov A.G., Kotlyar V.V.Effect of Optical “Dipoles” on the Topological Charge of a Beam // Nanobiotechnology Reports 2022. — Vol. 17. Issue 6. № 6. — P. 915-919
17Kotlyar V.V., Kovalev A.A., Nalimov A.G.Superposition of two Laguerre-Gaussian beams shifted from the optical axis // Computer Optics 2022. — Vol. 46. Issue 3. № 3. — P. 366-374
2003
1Khonina S.N., Kotlyar V.V., Skidanov R.V. etc. Optodigital system for identifying fingerprints in real time // Journal of Optical Technology 2003. — Vol. 70. Issue 8. — P. 586-589